{"id":4405,"date":"2021-12-21T11:56:41","date_gmt":"2021-12-21T11:56:41","guid":{"rendered":"https:\/\/bioingenieria.zeus.umh.es\/biomateriales\/"},"modified":"2022-11-29T16:11:01","modified_gmt":"2022-11-29T16:11:01","slug":"biomateriales","status":"publish","type":"page","link":"https:\/\/bioingenieria.umh.es\/en\/unidad-de-biomateriales-y-fotonica\/biomateriales\/","title":{"rendered":"Biomateriales"},"content":{"rendered":"

[et_pb_section fb_built=”1″ fullwidth=”on” disabled_on=”on|on|on” admin_label=”Secci\u00f3n” _builder_version=”4.16″ disabled=”on” global_colors_info=”{}”][et_pb_fullwidth_header title=”Biomateriales” text_orientation=”center” content_max_width=”none” admin_label=”T\u00edtulo de anchura completa” _builder_version=”4.16″ background_color=”#649922″ button_one_letter_spacing_hover=”0″ button_two_letter_spacing_hover=”0″ global_colors_info=”{}” button_one_text_size__hover_enabled=”off” button_two_text_size__hover_enabled=”off” button_one_text_color__hover_enabled=”off” button_two_text_color__hover_enabled=”off” button_one_border_width__hover_enabled=”off” button_two_border_width__hover_enabled=”off” button_one_border_color__hover_enabled=”off” button_two_border_color__hover_enabled=”off” button_one_border_radius__hover_enabled=”off” button_two_border_radius__hover_enabled=”off” button_one_letter_spacing__hover_enabled=”on” button_one_letter_spacing__hover=”0″ button_two_letter_spacing__hover_enabled=”on” button_two_letter_spacing__hover=”0″ button_one_bg_color__hover_enabled=”off” button_two_bg_color__hover_enabled=”off”][\/et_pb_fullwidth_header][\/et_pb_section][et_pb_section fb_built=”1″ disabled_on=”on|on|on” admin_label=”section” _builder_version=”4.16″ disabled=”on” global_colors_info=”{}”][et_pb_row padding_mobile=”off” column_padding_mobile=”on” admin_label=”row” _builder_version=”4.16″ background_size=”initial” background_position=”top_left” background_repeat=”repeat” max_width=”980px” make_fullwidth=”off” use_custom_width=”on” width_unit=”on” custom_width_px=”980px” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ custom_padding=”|||” global_colors_info=”{}” custom_padding__hover=”|||”][et_pb_tabs admin_label=”Pesta\u00f1as” _builder_version=”4.16″ tab_font=”Roboto||||” tab_line_height=”1.4em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” use_border_color=”off” border_color=”#ffffff” border_style=”solid” global_colors_info=”{}”][et_pb_tab title=”Informaci\u00f3n” _builder_version=”4.16″ body_font=”||||” body_line_height=”2em” tab_font=”||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n\n\n\n
Responsable<\/strong><\/td>\nPiedad N de Aza Moya<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

 <\/p>\n

RESUMEN DE LA INVESTIGACI\u00d3N<\/strong><\/h4>\n

Los biomateriales son ampliamente utilizados en la actualidad en todas las especialidades cl\u00ednicas y agrupan a todas las clases y subclases de materiales. Ocupan un lugar importante en la econom\u00eda moderna y en la sociedad debido a una creciente demanda. La raz\u00f3n principal de esto es el aumento de la esperanza de vida y la morbilidad de los traumatismos causados por accidentes de tr\u00e1fico, el deporte y los conflictos armados. Estos traumas, en general, perjudican seriamente a \u00f3rganos vivos que deben ser sustituidos total o parcialmente con materiales que mantengan sus propiedades funcionales o estructurales. A pesar del gran n\u00famero de desarrollos realizados en el campo de la ciencia y tecnolog\u00eda de los biomateriales en los \u00faltimos a\u00f1os, en la actualidad, no hay ning\u00fan biomaterial capaz de reproducir totalmente las caracter\u00edsticas y funciones del \u00f3rgano o el tejido original que remplaza. Este grupo persigue un prop\u00f3sito de gran incidencia social como es la mejora de la salud y de la calidad de vida de la poblaci\u00f3n a trav\u00e9s del dise\u00f1o y obtenci\u00f3n de nuevos biomateriales<\/p>\n

L\u00cdNEAS DE INVESTIGACI\u00d3N<\/strong><\/h4>\n

 <\/p>\n

L\u00ednea 1: <\/strong>ESTUDIO Y DETERMINACI\u00d3N DE DIAGRAMAS DE EQUILIBRIO DE FASES EN SISTEMAS DE \u00d3XIDOS.<\/strong><\/h4>\n

Las actividades de investigaci\u00f3n se apoyan fundamentalmente en el estudio te\u00f3rico y experimental de diagramas de equilibrio de fases. Estamos dedicados a aumentar el conocimiento b\u00e1sico de la termodin\u00e1mica, la s\u00edntesis, el procesamiento, las propiedades y el rendimiento en servicio de los materiales cer\u00e1micos.\u00a0 Realizamos trabajos relacionados con el campo de las biocer\u00e1micas para ingenier\u00eda y regeneraci\u00f3n \u00f3sea guiada, donde tambi\u00e9n se aplica el conocimiento en diagramas de equilibrio de fases. El grupo de investigaci\u00f3n acumula m\u00e1s de 20 a\u00f1os de experiencia en el uso de t\u00e9cnicas de transformaciones de fases basadas en an\u00e1lisis t\u00e9rmico diferencial, difracci\u00f3n de rayos X, para estudios de reacciones en estado s\u00f3lido y mecanismos de transformaci\u00f3n.<\/p>\n

\"linea1-biomateriales\"<\/p>\n

Subsistema silicocarnotita-fase A y material con microestructura eutectoide.<\/em><\/p>\n

 <\/p>\n

L\u00ednea 2: <\/strong>DESARROLLO DE ESTRUCTURAS DE ANDAMIAJE (SCAFFOLDS) OPTIMIZADAS<\/strong><\/h4>\n

Desarrollamos nuevos materiales, capaces de dar soluci\u00f3n a diversos problemas \u00f3seos. Las estructuras 3D con porosidad interconectada satisfacen requisitos generales como, por ejemplo, permitir la migraci\u00f3n celular, la difusi\u00f3n de residuos y nutrientes. Adem\u00e1s, dependiendo de la composici\u00f3n qu\u00edmica de la estructura 3D, es posible obtener una excelente bioactividad in vitro y biocompatibilidad in vivo.<\/p>\n

Nuestro grupo, a partir del conocimiento adquirido en el desarrollo de materiales densos, comenz\u00f3 con el desarrollo de materiales monocomposicional, intentando unificar resistencia mec\u00e1nica con bioactividad. Asi desarrollamos cer\u00e1micas 3D con distintas microestructuras mediante la t\u00e9cnica de r\u00e9plica polim\u00e9rica. Tambi\u00e9n obtenemos estructuras 3D multicomposicionales, compuestas por un n\u00facleo, constituido de una composici\u00f3n que proporciona resistencia mec\u00e1nica al material (entre 0.9 – 1.8MPa), que a su vez es recubierto por diversas capas de composici\u00f3n distinta al coraz\u00f3n, encargadas de modular la bioactividad del material. Las capas externas pueden tener la misma composici\u00f3n o cambiar la composici\u00f3n de capa a capa, con lo que se puede obtener un material con distintas composiciones, donde la primera le confiere a la estructura 3D propiedades mec\u00e1nicas y las capas superiores modulan la bioactividad, seg\u00fan los requerimientos del paciente, ya sea hombre o mujer.<\/p>\n

\"linea1-biomateriales\"<\/p>\n

Esquema de un andamio 3\u00b7D multicapa y material cer\u00e1mico 3D<\/em><\/p>\n

 <\/p>\n

L\u00ednea 3: INGENIERIA DE TEJIDO \u00d3SEO<\/strong><\/h4>\n

Uno de los retos del siglo XXI en biomedicina es lograr materiales capaces de estimular la regeneraci\u00f3n y la reparaci\u00f3n de tejidos \u00f3seos da\u00f1ados. En ingenier\u00eda de tejidos \u00f3seo se necesita una nueva generaci\u00f3n de materiales multifuncionales que act\u00faen temporalmente soportando y estimulando la adhesi\u00f3n, diferenciaci\u00f3n y colonizaci\u00f3n de las c\u00e9lulas osteoprogenitoras y que fomenten la vascularizaci\u00f3n. Esos materiales deben ser capaces de actuar como portadores de factores osteoinductivos y que promuevan la angiog\u00e9nesis y\/o de f\u00e1rmacos con una acci\u00f3n terap\u00e9utica, a la vez que dosifiquen su liberaci\u00f3n al entorno biol\u00f3gico. Los nuevos andamios deben poseer una resistencia mec\u00e1nica inicial semejante a la del tejido que remplazan, y degradarse en el sitio de implantaci\u00f3n a una velocidad semejante a la que crece el nuevo tejido.<\/p>\n

Con este obtetivo procedemos a dise\u00f1ar, procesar, preparar, caracterizar y estudiar in vitro e in vivo materiales a medida, en forma de granulados, cementos o andamiajes, con elevada macroporosidad interconectada, que permitan el ajuste de la tasa de biorreabsorbilidad y de liberaci\u00f3n de oligoelementos y\/o principios activos, todo ello, con objeto de modular su capacidad osteoinductiva y\/o angiog\u00e9nica.<\/p>\n

\"linea1-biomateriales\"<\/p>\n

Comparativa entre un material cer\u00e1mico 3D y un hueso esponjoso natural<\/em><\/p>\n

 [\/et_pb_tab][et_pb_tab title=”Miembros” _builder_version=”4.16″ body_font=”Roboto||||” body_line_height=”2em” tab_font=”Roboto||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n\n\n\n\n\n\n\n\n\n\n
Nombre<\/strong><\/td>\nPuesto<\/strong><\/td>\nCorreo<\/strong><\/td>\nORCID<\/strong><\/td>\n<\/tr>\n
De Aza Moya, Piedad N<\/td>\nCatedr\u00e1tica de Universidad<\/td>\npiedad@umh.es<\/a><\/td>\n0000-0001-9316-4407<\/td>\n<\/tr>\n
De la Casa Lillo, Miguel A<\/td>\nCatedr\u00e1tico de Universidad<\/td>\nmcasa@umh.es<\/a><\/td>\n0000-0002-7017-2225<\/td>\n<\/tr>\n
Velasquez Castillo, Pablo<\/td>\nProfesor Titular de Universidad<\/td>\npavelasquez@umh.es<\/a><\/td>\n0000-0002-5142-4992<\/td>\n<\/tr>\n
Mazon Canales, Patricia<\/td>\nProfesora Titular de Universidad<\/td>\npmazon@umh.es<\/a><\/td>\n0000-0001-7704-7577<\/td>\n<\/tr>\n
Murciano Cases, \u00c1ngel<\/td>\nProfesor Titular de Universidad<\/td>\namurciano@umh.es<\/a><\/td>\n0000-0003-1658-8446<\/td>\n<\/tr>\n
Anabel Diaz, Arca<\/td>\nContrato Predoctoral UMH<\/td>\nanabel.diaz@umh.es<\/a><\/td>\n0000-0001-7925-9258<\/td>\n<\/tr>\n
Nayarit Mata, Alayon<\/td>\nContrato Predoctoral Santiago Grisolia – GVA<\/td>\nnmata@umh.es<\/a><\/td>\n0000-0002-7310-683X<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

\"Foto<\/p>\n

[\/et_pb_tab][et_pb_tab title=”Publicaciones” _builder_version=”4.16″ body_font=”Roboto||||” body_line_height=”2em” tab_font=”Roboto||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

C. Naval\u00f3n, P. Maz\u00f3n, P.N. De Aza
\nEutectoid dicalcium silicate-Nurse\u00b4s A ceramic scaffold: processing and in vitro bioactivity<\/a><\/strong>
\nCeramic international (2019)<\/p>\n

P.Maz\u00f3n, P.Ros-T\u00e1rraga, S. Serena, L. Meseguer-Olmo, P.N. De Aza
\nIn vitro bioactivity and cell biocompatibility of a hypereutectic bioceramic<\/a><\/strong>
\nSymmetry (2019)<\/p>\n

A. Diaz-Arca, P. Maz\u00f3n, P.N. de Aza
\nEutectoid scaffold as potential tissue engineer guide<\/a><\/strong>
\nJ. Am. Ceram. Soc. 102 (12) :7168\u20137177 (2019).<\/p>\n

N.A. Mata, P. Ros-T\u00e1rraga, P. Velasquez, A. Murciano, P.N. De Aza
\nSynthesis and Characterization of 3D multilayer porous Si-Ca-P scaffolds doped with Sr ions to modulate in vitro bioactivity<\/a><\/strong>
\nCeramic international. 46 (1) 968\u2013977 (2020).<\/p>\n

A. D\u00edaz-Arca, P. Ros-T\u00e1rraga, P. Velasquez, P. Maz\u00f3n, P.N. de Aza
\nMechanism of in vitro reaction of a new scaffold ceramic similar to a porous bone<\/a><\/strong>
\nJournal of the European Ceramic Society 40 (5), 2200-2206 (2020).<\/p>\n

N.A. Mata, P. Ros-T\u00e1rraga, P. Velasquez, A. Murciano, P.N. De Aza
\nNew iron-doped multilayer ceramic scaffold with non-continuous bioactive behavior<\/a><\/strong>
\nCeramics international 46 (2020) 16388\u201316396 (2020).<\/p>\n

P. Ros-T\u00e1rraga, P. Maz\u00f3n, B. Revilla-Nuin, R. Rabad\u00e1n-Ros, P.N. de Aza, L. Meseguer-Olmo
\nHigh temperature CaSiO3-Ca3(PO4)2 ceramic promotes osteogenic differentiation in adult human mesenchymal stem cells<\/a><\/strong>
\nMaterials Science & Engineering C – 107 110355 (2020).<\/p>\n

A. Diaz-Arca, P. Ros-T\u00e1rraga ,P. Maz\u00f3n, P.N. de Aza
\nIn vitro characterization of new biphasic scaffolds in the sub-system Ca3(PO4)2 – 5CaO\u00b7SiO2\u00b7P2O5<\/a><\/strong>
\nCeramics international 46 (2020) 18123\u201318130 (2020).<\/p>\n

A. D\u00edaz-Arca, P. Ros-T\u00e1rraga,M.J. Martinez-Tom\u00e9, A.H. De Aza, L. Meseguer-Olmo, P. Maz\u00f3n, P.N. De Aza
\nMicro-\/Nano-Structure Ceramic scaffolds that mimic natural cancellous bone<\/a><\/strong>
\nMaterials 2021, 14, 1439 (2021).<\/p>\n

N. A. Mata, P. Ros- T\u00e1rraga; P.Vel\u00e1squez; \u00c1. Murciano; P. N De Aza
\n3D multiphasic and multilayer porous scaffolds of calcium phosphates doping with silicon and magnesium Andamios porosos multif\u00e1sicos 3D de fosfatos c\u00e1lcicos dopados con silicio y magnesio<\/a><\/strong>
\nBol. Soc. Esp. Ceram. Vidrio (2021).<\/p>\n

[\/et_pb_tab][et_pb_tab title=”Proyectos” _builder_version=”4.16″ body_font=”||||” body_line_height=”2em” tab_font=”||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

Estructuras soporte con morfolog\u00eda superficial potenciadoras del crecimiento y diferenciaci\u00f3n celular (PID2020-116693RB-C21). Financiado por MCIN\/AEI\/ 10.13039\/501100011033. Vigencia: 2021-2024
\nPI: PI: Piedad N. De Aza Moya<\/em><\/p>\n

\n

Footwear in the 21st century: New skills for the design of drastically improved comfort, sustainable, fashion-oriented and scientifically-led footwear products\u201d (SciLED). Agencia de financiaci\u00f3n: Uni\u00f3n Europea- .601137-EPP-1-2018-1-RO-EPPKA2-KA. Vigencia: 01\/01\/2019 – 31\/12\/2021.
\nPI: Miguel \u00c1ngel De la Casa Lillo<\/em><\/p>\n

\n

S\u00edntesis, caracterizaci\u00f3n y biocompatibilidad de andamios cer\u00e1micos realizados con materiales de tercera generaci\u00f3n. Ayudas del programa Santiago Grisol\u00eda para la contrataci\u00f3n de personal investigador en formaci\u00f3n de car\u00e1cter predoctoral. Agencia de financiaci\u00f3n: Conselleria de Educaci\u00f3n, Investigaci\u00f3n, Cultura y Deportes. Vigencia: 2018-2021.
\nPI: Piedad Nieves de Aza Moya<\/em><\/p>\n

\n

Biomateriales cer\u00e1micos multifuncionales con estructuras jerarquizadas para regeneraci\u00f3n \u00f3sea y\/o liberaci\u00f3n controlada de agentes biol\u00f3gicos. Agencia de financiaci\u00f3n: Ministerio de Econom\u00eda y Competitividad. Vigencia: 2014-2017.
\nPI: Piedad Nieves de Aza Moya<\/em><\/p>\n

[\/et_pb_tab][\/et_pb_tabs][\/et_pb_column][\/et_pb_row][et_pb_row padding_mobile=”off” column_padding_mobile=”on” disabled_on=”on|on|on” admin_label=”row” _builder_version=”4.16″ background_size=”initial” background_position=”top_left” background_repeat=”repeat” max_width=”980px” make_fullwidth=”off” use_custom_width=”on” width_unit=”on” custom_width_px=”980px” disabled=”on” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ custom_padding=”|||” global_colors_info=”{}” custom_padding__hover=”|||”][et_pb_tabs admin_label=”Pesta\u00f1as” _builder_version=”4.16″ tab_font=”Roboto||||” tab_line_height=”1.4em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” use_border_color=”off” border_color=”#ffffff” border_style=”solid” global_colors_info=”{}”][et_pb_tab title=”Informaci\u00f3n” _builder_version=”4.16″ body_font=”||||” body_line_height=”2em” tab_font=”||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n\n\n\n
Responsable<\/strong><\/td>\nPiedad N de Aza Moya<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

 <\/p>\n

RESUMEN DE LA INVESTIGACI\u00d3N<\/strong><\/h4>\n

El grupo est\u00e1 formado por investigadores y becarios de formaci\u00f3n dentro del \u00e1rea de conocimiento de Ciencia de Materiales e Ingenier\u00eda Metal\u00fargica. Se trata de un grupo multidisciplinar formado por especialistas en diversas disciplinas como f\u00edsica, qu\u00edmica, ingenier\u00eda de materiales etc.
\nNuestro principal objetivo se centra en el dise\u00f1o, desarrollo, caracterizaci\u00f3n de materiales.<\/p>\n

L\u00cdNEAS DE INVESTIGACI\u00d3N<\/strong><\/h4>\n

 <\/p>\n

L\u00ednea 1: Biomateriales<\/strong><\/h4>\n

Los biomateriales son ampliamente utilizados en la actualidad en todas las especialidades cl\u00ednicas y agrupan a todas las clases y subclases de materiales, es decir, metales, pol\u00edmeros, cer\u00e1micas y materiales compuestos, entre otros. Ocupan un lugar importante en la econom\u00eda moderna y en la sociedad debido a una creciente demanda. La raz\u00f3n principal de esto es el aumento de la esperanza de vida y la morbilidad de los traumatismos causados por accidentes de tr\u00e1fico, el deporte y los conflictos armados. Estos traumas, en general, perjudican seriamente a \u00f3rganos vivos que deben ser sustituidos total o parcialmente con materiales que mantengan sus propiedades funcionales o estructurales.
\nA pesar del gran n\u00famero de desarrollos realizados en el campo de la ciencia y tecnolog\u00eda de los biomateriales en los \u00faltimos a\u00f1os, en la actualidad, no hay ning\u00fan biomaterial capaz de reproducir totalmente las caracter\u00edsticas y funciones del \u00f3rgano o el tejido original que remplaza.
\nEste grupo persigue un prop\u00f3sito de gran incidencia social como es la mejora de la salud y de la calidad de vida de la poblaci\u00f3n a trav\u00e9s del dise\u00f1o y obtenci\u00f3n de nuevos biomateriales.<\/p>\n

\"linea1-biomateriales\"<\/p>\n

Imagen de SEM de un material cer\u00e1mico bioactivo donde se ha producido un precipitado de hidroxiapatito, componente mineral inorg\u00e1nico del tejido \u00f3seo.<\/em><\/p>\n

[\/et_pb_tab][et_pb_tab title=”Miembros” _builder_version=”4.16″ body_font=”Roboto||||” body_line_height=”2em” tab_font=”Roboto||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n\n\n\n\n\n\n\n\n\n\n
Nombre<\/strong><\/td>\nPuesto<\/strong><\/td>\nCorreo<\/strong><\/td>\nORCID<\/strong><\/td>\n<\/tr>\n
De Aza Moya, Piedad N<\/td>\nCatedr\u00e1tica de Universidad<\/td>\npiedad@umh.es<\/a><\/td>\n0000-0001-9316-4407<\/td>\n<\/tr>\n
De la Casa Lillo, Miguel A<\/td>\nCatedr\u00e1tico de Universidad<\/td>\nmcasa@umh.es<\/a><\/td>\n0000-0002-7017-2225<\/td>\n<\/tr>\n
Velasquez Castillo, Pablo<\/td>\nProfesor Titular de Universidad<\/td>\npavelasquez@umh.es<\/a><\/td>\n0000-0002-5142-4992<\/td>\n<\/tr>\n
Mazon Canales, Patricia<\/td>\nProfesor Titular de Universidad<\/td>\npmazon@umh.es<\/a><\/td>\n0000-0001-7704-7577<\/td>\n<\/tr>\n
Murciano Cases, \u00c1ngel<\/td>\nProfesor Titular de Universidad<\/td>\namurciano@umh.es<\/a><\/td>\n0000-0003-1658-8446<\/td>\n<\/tr>\n
Anabel Diaz, Arca<\/td>\nContrato Predoctoral UMH<\/td>\nanabel.diaz@umh.es<\/a><\/td>\n0000-0001-7925-9258<\/td>\n<\/tr>\n
Nayarit Mata, Alayon<\/td>\nContrato Predoctoral Santiago Crisolia – GVA<\/td>\nnmata@umh.es<\/a><\/td>\n0000-0002-7310-683X<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

[\/et_pb_tab][et_pb_tab title=”Publicaciones” _builder_version=”4.16″ body_font=”Roboto||||” body_line_height=”2em” tab_font=”Roboto||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

C. Naval\u00f3n, P. Maz\u00f3n, P.N. De Aza
\nEutectoid dicalcium silicate-Nurse\u00b4s A ceramic scaffold: processing and in vitro bioactivity<\/a><\/strong>
\nCeramic international (2019)<\/p>\n

P.Maz\u00f3n, P.Ros-T\u00e1rraga, S. Serena, L. Meseguer-Olmo, P.N. De Aza
\nIn vitro bioactivity and cell biocompatibility of a hypereutectic bioceramic<\/a><\/strong>
\nSymmetry (2019)<\/p>\n

A. Diaz-Arca, P. Maz\u00f3n, P.N. de Aza
\nEutectoid scaffold as potential tissue engineer guide<\/a><\/strong>
\nJ. Am. Ceram. Soc. 102 (12) :7168\u20137177 (2019).<\/p>\n

N.A. Mata, P. Ros-T\u00e1rraga, P. Velasquez, A. Murciano, P.N. De Aza
\nSynthesis and Characterization of 3D multilayer porous Si-Ca-P scaffolds doped with Sr ions to modulate in vitro bioactivity<\/a><\/strong>
\nCeramic international. 46 (1) 968\u2013977 (2020).<\/p>\n

A. D\u00edaz-Arca, P. Ros-T\u00e1rraga, P. Velasquez, P. Maz\u00f3n, P.N. de Aza
\nMechanism of in vitro reaction of a new scaffold ceramic similar to a porous bone<\/a><\/strong>
\nJournal of the European Ceramic Society 40 (5), 2200-2206 (2020).<\/p>\n

N.A. Mata, P. Ros-T\u00e1rraga, P. Velasquez, A. Murciano, P.N. De Aza
\nNew iron-doped multilayer ceramic scaffold with non-continuous bioactive behavior<\/a><\/strong>
\nCeramics international 46 (2020) 16388\u201316396 (2020).<\/p>\n

P. Ros-T\u00e1rraga, P. Maz\u00f3n, B. Revilla-Nuin, R. Rabad\u00e1n-Ros, P.N. de Aza, L. Meseguer-Olmo
\nHigh temperature CaSiO3-Ca3(PO4)2 ceramic promotes osteogenic differentiation in adult human mesenchymal stem cells<\/a><\/strong>
\nMaterials Science & Engineering C – 107 110355 (2020).<\/p>\n

A. Diaz-Arca, P. Ros-T\u00e1rraga ,P. Maz\u00f3n, P.N. de Aza
\nIn vitro characterization of new biphasic scaffolds in the sub-system Ca3(PO4)2 – 5CaO\u00b7SiO2\u00b7P2O5<\/a><\/strong>
\nCeramics international 46 (2020) 18123\u201318130 (2020).<\/p>\n

A. D\u00edaz-Arca, P. Ros-T\u00e1rraga,M.J. Martinez-Tom\u00e9, A.H. De Aza, L. Meseguer-Olmo, P. Maz\u00f3n, P.N. De Aza
\nMicro-\/Nano-Structure Ceramic scaffolds that mimic natural cancellous bone<\/a><\/strong>
\nMaterials 2021, 14, 1439 (2021).<\/p>\n

N. A. Mata, P. Ros- T\u00e1rraga; P.Vel\u00e1squez; \u00c1. Murciano; P. N De Aza
\n3D multiphasic and multilayer porous scaffolds of calcium phosphates doping with silicon and magnesium Andamios porosos multif\u00e1sicos 3D de fosfatos c\u00e1lcicos dopados con silicio y magnesio<\/a><\/strong>
\nBol. Soc. Esp. Ceram. Vidrio (2021).<\/p>\n

[\/et_pb_tab][et_pb_tab title=”Proyectos” _builder_version=”4.16″ body_font=”||||” body_line_height=”2em” tab_font=”||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

Footwear in the 21st century: New skills for the design of drastically improved comfort, sustainable, fashion-oriented and scientifically-led footwear products\u201d (SciLED). Agencia de financiaci\u00f3n: Uni\u00f3n Europea- .601137-EPP-1-2018-1-RO-EPPKA2-KA. Vigencia: 01\/01\/2019 – 31\/12\/2021.
\nPI: Miguel \u00c1ngel De la Casa Lillo<\/em><\/p>\n

\n

S\u00edntesis, caracterizaci\u00f3n y biocompatibilidad de andamios cer\u00e1micos realizados con materiales de tercera generaci\u00f3n. Ayudas del programa Santiago Grisol\u00eda para la contrataci\u00f3n de personal investigador en formaci\u00f3n de car\u00e1cter predoctoral. Agencia de financiaci\u00f3n: Conselleria de Educaci\u00f3n, Investigaci\u00f3n, Cultura y Deportes. Vigencia: 2018-2021.
\nPI: Piedad Nieves de Aza Moya<\/em><\/p>\n

\n

Biomateriales cer\u00e1micos multifuncionales con estructuras jerarquizadas para regeneraci\u00f3n \u00f3sea y\/o liberaci\u00f3n controlada de agentes biol\u00f3gicos. Agencia de financiaci\u00f3n: Ministerio de Econom\u00eda y Competitividad. Vigencia: 2014-2017.
\nPI: Piedad Nieves de Aza Moya<\/em><\/p>\n

\n

Ayuda complementaria al proyecto “S\u00edntesis y obtenci\u00f3n de nuevos biomateriales basados en fosfato tric\u00e1lcico y s\u00edlico-fosfatos de calcio. Estudios in vitro e in vivo. Agencia de financiaci\u00f3n: Conselleria de Empresa, Universidad i Ciencia, Generalitat Valencian. Vigencia: 2009.
\nPI: Piedad Nieves de Aza Moya<\/em><\/p>\n

\n

Ayuda complementaria al proyecto: “Obtenci\u00f3n de biomateriales cer\u00e1micos en el sistema fosfato tric\u00e1lcico-silicato dic\u00e1lcico-s\u00edlice. Estudios “in vivo e in vitro”. Agencia de financiaci\u00f3n: Conselleria de Empresa, Universidad i Ciencia – Generalitat Valenciana. Vigencia: 2006.
\nPI: Piedad Nieves de Aza Moya<\/em><\/p>\n

[\/et_pb_tab][\/et_pb_tabs][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ fullwidth=”on” disabled_on=”off|off|off” admin_label=”Secci\u00f3n” _builder_version=”4.16″ global_colors_info=”{}”][et_pb_fullwidth_header title=”Biomaterials” text_orientation=”center” content_max_width=”none” admin_label=”T\u00edtulo de anchura completa” _builder_version=”4.16″ background_color=”#649922″ button_one_letter_spacing_hover=”0″ button_two_letter_spacing_hover=”0″ global_colors_info=”{}” button_one_text_size__hover_enabled=”off” button_two_text_size__hover_enabled=”off” button_one_text_color__hover_enabled=”off” button_two_text_color__hover_enabled=”off” button_one_border_width__hover_enabled=”off” button_two_border_width__hover_enabled=”off” button_one_border_color__hover_enabled=”off” button_two_border_color__hover_enabled=”off” button_one_border_radius__hover_enabled=”off” button_two_border_radius__hover_enabled=”off” button_one_letter_spacing__hover_enabled=”on” button_one_letter_spacing__hover=”0″ button_two_letter_spacing__hover_enabled=”on” button_two_letter_spacing__hover=”0″ button_one_bg_color__hover_enabled=”off” button_two_bg_color__hover_enabled=”off”][\/et_pb_fullwidth_header][\/et_pb_section][et_pb_section fb_built=”1″ disabled_on=”off|off|off” admin_label=”section” _builder_version=”4.16″ global_colors_info=”{}”][et_pb_row padding_mobile=”off” column_padding_mobile=”on” admin_label=”row” _builder_version=”4.16″ background_size=”initial” background_position=”top_left” background_repeat=”repeat” max_width=”980px” make_fullwidth=”off” use_custom_width=”on” width_unit=”on” custom_width_px=”980px” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ custom_padding=”|||” global_colors_info=”{}” custom_padding__hover=”|||”][et_pb_tabs admin_label=”Pesta\u00f1as” _builder_version=”4.17.4″ tab_font=”Roboto||||” tab_line_height=”1.4em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” use_border_color=”off” border_color=”#ffffff” border_style=”solid” global_colors_info=”{}”][et_pb_tab title=”Information” _builder_version=”4.16″ body_font=”||||” body_line_height=”2em” tab_font=”||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

 <\/p>\n\n\n\n
Responsible<\/strong><\/td>\nPiedad N de Aza Moya<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

 <\/p>\n

RESEARCH SUMMARY<\/strong><\/h4>\n

Biomaterials are widely used today in all clinical specialties and include all classes and subclasses of materials. They have an important place in the modern economy and in society due to a growing demand. The main reason for this is the increase in life expectancy and the morbidity of injuries caused by traffic accidents, sports and armed conflicts. These traumas, in general, seriously damage living organs that must be totally or partially replaced with materials that maintain their functional or structural properties.
Despite the large number of developments in the field of biomaterial science and technology in recent years, there is currently no biomaterial capable of fully reproducing the characteristics and functions of the original organ or tissue that it replaces.
The purpose of this group have a great social impact such as improving the health and quality of life of the population through the design and obtaining of new biomaterials.
<\/span><\/p>\n

RESEARCH LINES<\/strong><\/h4>\n

 <\/p>\n

PHASE EQUILIBRIUM DIAGRAMS IN OXIDE SYSTEMS<\/strong><\/h4>\n

Research activities are mainly based on the theoretical and experimental study of phase equilibrium diagrams. We are dedicated to increasing the basic knowledge of thermodynamics, synthesis, processing, properties and service performance of ceramic materials. Work in the field of bioceramics for bone engineering and guided bone regeneration, which applied the knowledge in phase equilibrium diagrams, were stared in 1995. The research group accumulates more than 20 years of experience in the use of phase transformation techniques based on differential thermal analysis, X-ray diffraction, for studies of solid state reactions and transformation mechanisms.<\/span>\u00a0<\/span><\/p>\n

\"linea1-biomateriales\"<\/p>\n

Silicocarnotite-phase A subsystem and material with eutectoid microstructure.<\/em><\/p>\n

 <\/p>\n

DEVELOPMENT OF 3D OPTIMIZED SCAFFOLDS<\/strong><\/h4>\n

We develop new materials capable of solving various bone problems. 3D structures with interconnected porosity meet general requirements such as allowing cell migration, diffusion of debris and nutrients. Furthermore, depending on the chemical composition of the 3D structure, it is possible to obtain excellent in vitro bioactivity and in vivo biocompatibility.
Our group, based on the knowledge acquired in the development of dense materials, began with the development of monocompositional materials, trying to unify mechanical resistance with bioactivity. Thus we develop 3D ceramics with different microstructures using the polymeric replica technique. We also obtain multicompositional 3D structures, composed of a core, made up of a composition that provides mechanical resistance to the material (between 0.9 – 1.8MPa), which in turn is covered by various layers of composition other than the heart, responsible for modulating the bioactivity of the material. The external layers can have the same composition or change the composition from layer to layer, with which a material with different compositions can be obtained, where the first gives the 3D structure mechanical properties and the upper layers modulate the bioactivity, depending on the requirements of the patient, whether male or female.
<\/span><\/p>\n

\"linea1-biomateriales\"<\/p>\n

Schematic representation of a 3D multilayer scaffold and 3D ceramic material<\/em><\/p>\n

 <\/p>\n

BONE TISSUE ENGINEERING\u00a0<\/strong><\/h4>\n

One of the challenges of the 21st century in biomedicine is to achieve materials capable of stimulating the regeneration and repair of damaged bone tissues. In bone tissue engineering, a new generation of multifunctional materials is needed that temporarily act to support and stimulate the adhesion, differentiation and colonization of osteoprogenitor cells and that promote vascularization. These materials must be capable of acting as carriers of osteoinductive factors and that promote angiogenesis and \/ or drugs with a therapeutic action, at the same time that they dose their release to the biological environment. New scaffolds must have an initial mechanical strength similar to that of the tissue they replace, and degrade at the implantation site at a rate similar to that at which the new tissue grows.
With this objective in mind, we proceed to design, process, prepare, characterize and study in vitro and in vivo custom materials, in the form of granules, cements or scaffolds, with high interconnected macroporosity, which allow the adjustment of the bioresorbability and release rate of trace elements and \/ or active principles, all in order to modulate their osteoinductive and \/ or angiogenic capacity.
<\/span><\/p>\n

\"linea1-biomateriales\"<\/p>\n

Comparison between a 3D ceramic material and a natural cancellous bone<\/em><\/p>\n

 <\/p>\n

.<\/em><\/p>\n

<!–\u00a0<\/p>\n\n\n\n
Responsible<\/strong><\/td>\nPiedad N de Aza Moya<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

 <\/p>\n

RESEARCH SUMMARY<\/strong><\/h4>\n

Biomaterials are widely used today in all clinical specialties and include all classes and subclasses of materials. They have an important place in the modern economy and in society due to a growing demand. The main reason for this is the increase in life expectancy and the morbidity of injuries caused by traffic accidents, sports and armed conflicts. These traumas, in general, seriously damage living organs that must be totally or partially replaced with materials that maintain their functional or structural properties.<\/span><\/p>\n

Despite the large number of developments in the field of biomaterial science and technology in recent years, there is currently no biomaterial capable of fully reproducing the characteristics and functions of the original organ or tissue that it replaces.\u00a0<\/span>The purpose of this group has a great social impact such as improving the health and quality of life of the population through the design and obtention of new biomaterials.<\/span><\/p>\n

 <\/p>\n

RESEARCH LINES<\/strong><\/h4>\n

 <\/p>\n

Line1: Biomaterials phase equilibrium diagrams in oxide systems<\/strong><\/h4>\n

Research activities are mainly based on the theoretical and experimental study of phase equilibrium diagrams. We are dedicated to increasing the basic knowledge of thermodynamics, synthesis, processing, properties and service performance of ceramic materials. Work in the field of bioceramics for bone engineering and guided bone regeneration, which applied the knowledge in phase equilibrium diagrams, were stared in 1995. The research group accumulates more than 20 years of experience in the use of phase transformation techniques based on differential thermal analysis, X-ray diffraction, for studies of solid state reactions and transformation mechanisms.<\/span>\u00a0<\/span><\/p>\n

\"linea1-biomateriales\"<\/p>\n

Silicocarnotite-phase A subsystem and material with eutectoid microstructure.<\/em><\/p>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n

Line2: Development of 3D optimized scaffolds<\/strong><\/h4>\n

We develop new materials capable of solving various bone problems. 3D structures with interconnected porosity meet general requirements such as allowing cell migration, diffusion of debris and nutrients. Furthermore, depending on the chemical composition of the 3D structure, it is possible to obtain excellent in vitro bioactivity and in vivo biocompatibility.<\/span><\/p>\n

Our group, based on the knowledge acquired in the development of dense materials, began with the development of monocompositional materials, trying to unify mechanical resistance with bioactivity. Thus we develop 3D ceramics with different microstructures using the polymeric replica technique. We also obtain multicompositional 3D structures, composed of a core, made up of a composition that provides mechanical resistance to the material (between 0.9 – 1.8MPa), which in turn is covered by various layers of composition other than the heart, responsible for modulating the bioactivity of the material. The external layers can have the same composition or change the composition from layer to layer, with which a material with different compositions can be obtained, where the first gives the 3D structure mechanical properties and the upper layers modulate the bioactivity, depending on the requirements of the patient, whether male or female.<\/span><\/p>\n

 <\/p>\n

Schematic representation of a 3D multilayer scaffold and 3D ceramic material<\/em><\/p>\n

 <\/p>\n

 <\/p>\n

Line3: Bone tissue engineering\u00a0<\/strong><\/h4>\n

One of the challenges of the 21st century in biomedicine is to achieve materials capable of stimulating the regeneration and repair of damaged bone tissues. In bone tissue engineering, a new generation of multifunctional materials is needed that temporarily act to support and stimulate the adhesion, differentiation and colonization of osteoprogenitor cells and that promote vascularization. These materials must be capable of acting as carriers of osteoinductive factors and that promote angiogenesis and \/ or drugs with a therapeutic action, at the same time that they dose their release to the biological environment. New scaffolds must have an initial mechanical strength similar to that of the tissue they replace, and degrade at the implantation site at a rate similar to that at which the new tissue grows.<\/span><\/p>\n

With this objective in mind, we proceed to design, process, prepare, characterize and study in vitro and in vivo custom materials, in the form of granules, cements or scaffolds, with high interconnected macroporosity, which allow the adjustment of the bioresorbability and release rate of trace elements and \/ or active principles, all in order to modulate their osteoinductive and \/ or angiogenic capacity.<\/span><\/p>\n

\n

\n

\n

Comparison between a 3D ceramic material and a natural cancellous bone<\/em><\/p>\n

\n\n\n\n\n
<\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

 <\/p>\n

<\/span><\/p>\n

 <\/p>\n

.<\/em><\/p>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n

–><\/p>\n

[\/et_pb_tab][et_pb_tab title=”Members” _builder_version=”4.17.4″ body_font=”Roboto||||” body_line_height=”2em” tab_font=”Roboto||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

 <\/p>\n\n\n\n\n\n\n\n\n\n\n\n\n
Name<\/strong><\/td>\nPosition<\/strong><\/td>\ne-mail<\/strong><\/td>\nORCID<\/strong><\/td>\n<\/tr>\n
Piedad De Aza Moya<\/td>\nFull Professor<\/td>\npiedad@umh.es<\/a><\/td>\n0000-0001-9316-4407<\/td>\n<\/tr>\n
Miguel \u00c1ngel De la Casa Lillo<\/td>\nFull Professor<\/td>\nmcasa@umh.es<\/a><\/td>\n0000-0002-7017-2225<\/td>\n<\/tr>\n
Pablo Vel\u00e1squez Castillo<\/td>\nAssociate Professor<\/td>\npavelasquez@umh.es<\/a><\/td>\n0000-0002-5142-4992<\/td>\n<\/tr>\n
Patricia Maz\u00f3n Canales<\/td>\nAssociate Professor<\/td>\npmazon@umh.es<\/a><\/td>\n0000-0001-7704-7577<\/td>\n<\/tr>\n
\u00c1ngel Murciano Cases<\/td>\nAssociate Professor<\/td>\namurciano@umh.es<\/a><\/td>\n0000-0003-1658-8446<\/td>\n<\/tr>\n
Karina Salazar Llangari<\/td>\nPredoctoral contract “Fundaci\u00f3n Carolina”<\/td>\nkarina.salazar@goumh.umh.es<\/a><\/td>\n<\/td>\n<\/tr>\n
Sergio A Gehrke<\/span><\/td>\nPostdoctoral Researcher \u00abMargarita Salas\u00bb<\/span><\/td>\nsgehrke@umh.es<\/a><\/td>\n0000-0002-5863-9101<\/span><\/td>\n<\/tr>\n
Paula\u00a0Riosalido De Lucas<\/span><\/td>\nResearch Technician ( GVA-AICO)<\/span><\/td>\npriosalido@umh.es<\/a><\/td>\n<\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/td>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

\"Foto<\/p>\n

[\/et_pb_tab][et_pb_tab title=”Publications” _builder_version=”4.16″ body_font=”Roboto||||” body_line_height=”2em” tab_font=”Roboto||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

P. Ros-T\u00e1rraga, C.M. Mart\u00ednez, M.A. Rodr\u00edguez, P.N. De Aza
3D calcium silicophosphate porous scaffold: in vitro and in vivo response<\/strong><\/a>
Ceramics International (2023).<\/p>\n

<\/span><\/p>\n

E. Sebasti\u00e1n, A. Murciano, P.N De Aza, P. Velasquez
<\/span>Synthesis of 3D porous ceramic scaffolds obtained by the sol-gel method with surface morphology modified by hollow spheres for bone tissue engineering applications<\/strong><\/a>
Ceramics International (2023).<\/p>\n

 <\/p>\n

N.A. Mata, M. Arango-Ospina, P. Velasquez, A. Murciano, P.N. De Aza, A.R. Boccaccini
Effect of Sr, Mg and Fe substitution on the physico-chemical and biological properties of Si-Ca-P multilayer scaffolds<\/strong><\/a>
Bolet\u00edn de la Sociedad Espa\u00f1ola de Cer\u00e1mica y Vidrio (2023).<\/p>\n

<\/span><\/p>\n

A. Gehrke, J. Arambur\u00fa J\u00fanior, T.L. Eirles Treichel, T.Dias do Prado, B.A. Dedavid, P.N. de Aza.
<\/span>Effects of insertion torque values on the marginal bone loss of dental implants installed in sheep mandibles<\/strong><\/a>
Scientific Reports 12, 538 (2022).<\/p>\n

<\/span><\/p>\n

A. Mata, P. Ros- T\u00e1rraga; P.Vel\u00e1squez; \u00c1. Murciano; P. N De Aza
<\/span>3D multiphasic and multilayer porous scaffolds of calcium phosphates doping with silicon and magnesium<\/strong><\/a>
Bolet\u00edn de la Sociedad Espa\u00f1ola de Cer\u00e1mica y Vidrio 61, 384-396 (2022).<\/p>\n

E. Sebasti\u00e1n, A.Murciano, R. Madrigal, P.N De Aza, P. Velasquez
<\/span>3D CaP porous scaffolds with grooved surface topography obtained by the sol-gel method <\/strong><\/a>
Ceramics International 47: 21466-21475\u00a0 (2021).<\/p>\n

 <\/p>\n

N.A. Mata, P. Velasquez, A. Murciano, P.N. De Aza
Multilayer Mg-pyrophosphate glass ceramic with discontinuous bioactivity. Physicochemical characterization.<\/a>
<\/strong>Ceramics International 47(10), 14612-14620 (2021).<\/p>\n

N.A. Mata, P. Ros-T\u00e1rraga, P. Velasquez, A. Murciano, P.N. De Aza
Synthesis and Characterization of 3D multilayer porous Si-Ca-P scaffolds doped with Sr ions to modulate in vitro bioactivity<\/a><\/strong>
Ceramics International. 46 (1) 968\u2013977 (2020).<\/p>\n

A. D\u00edaz-Arca, P. Ros-T\u00e1rraga, P. Velasquez, P. Maz\u00f3n, P.N. de Aza
Mechanism of in vitro reaction of a new scaffold ceramic similar to a porous bone<\/a><\/strong>
Journal of the European Ceramic Society 40 (5), 2200-2206 (2020).<\/p>\n

P. Ros-T\u00e1rraga, P. Maz\u00f3n, B. Revilla-Nuin, R. Rabad\u00e1n-Ros, P.N. de Aza, L. Meseguer-Olmo
High temperature CaSiO3-Ca3(PO4)2 ceramic promotes osteogenic differentiation in adult human mesenchymal stem cells<\/a><\/strong>
Materials Science & Engineering C – 107 110355 (2020).<\/p>\n

\n

[\/et_pb_tab][et_pb_tab title=”Projects” _builder_version=”4.16″ body_font=”||||” body_line_height=”2em” tab_font=”||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

Osteoinductive biomaterials in the treatment of necrotic lesions derived from radiotherapy, chemotherapy and drugs (CIAICO\/2021\/157)<\/span>. Funding agency: \u00a0<\/span>Conselleria de Innovaci\u00f3n, Ciencia y Sociedad Digital, <\/span>GVA.\u00a0<\/span>AICO Program for Consolidated Groups of the Valencian Community<\/span>. Duration: 2022-2024<\/p>\n

PI1: Piedad N. De Aza Moya\u00a0 \u00a0 \u00a0 \u00a0PI2: \u00c1ngel Murciano Cases<\/em><\/p>\n

\u00a0__________________________________________________________________________________________________________________________________<\/p>\n

Scaffolds with surface morphology enhancers of cell growth and differentiation (PID2020-116693RB-C21). Funding agency: Ministry of Science and Innovation MCIN\/AEI\/ 10.13039\/501100011033.\u00a0 Duration: 2021-2024<\/p>\n

PI: Piedad N. De Aza Moya<\/em><\/p>\n

\n

Footwear in the 21st century: New skills for the design of drastically improved comfort, sustainable, fashion-oriented and scientifically-led footwear products\u201d (SciLED). Funding agency: European Union- .601137-EPP-1-2018-1-RO-EPPKA2-KA. Duration: 01\/01\/2019 – 31\/12\/2021.<\/span><\/p>\n

PI: Miguel \u00c1ngel De la Casa Lillo<\/em><\/p>\n

\n

Synthesis, characterization and biocompatibility of ceramic scaffolds made with third generation materials. Grant from the Santiago Grisol\u00eda program for the hiring of research staff in predoctoral training. Funding agency: Conselleria de Educaci\u00f3n, Investigaci\u00f3n, Cultura y Deportes. Duration: 2018-2021.<\/span>\u00a0<\/span><\/p>\n

PI: Piedad N. de Aza Moya<\/em><\/p>\n

\n

Multifunctional ceramic biomateriales with hierarchized structures for bone regeneration\u00a0 and\/or controlled release of biological agents. Funding agency: Ministry of Economy and Competitivity. Duration: 2014-2017.<\/span><\/p>\n

PI: Piedad N. de Aza Moya<\/em><\/p>\n

[\/et_pb_tab][et_pb_tab title=”Activities” _builder_version=”4.16″ body_font=”||||” body_line_height=”2em” tab_font=”||||” tab_line_height=”2em” background_size=”initial” background_position=”top_left” background_repeat=”repeat” body_line_height_tablet=”2em” body_line_height_phone=”2em” tab_line_height_tablet=”2em” tab_line_height_phone=”2em” global_colors_info=”{}”]<\/p>\n

PhD Dissertations<\/strong><\/p>\n

Nayarit A. Mata Alayon (2022). Synthesis and characterization of multilayer 3D porous ceramic structures obtained through the sol-gel process for application in bone tissue engineering.<\/p>\n

Anabel Diaz Arca (2021). 3D tricalcium phosphate-silicocarnotite scaffolds with micro-\/nano-eutectoid structure and in situ formation of apatite.<\/p>\n

[\/et_pb_tab][\/et_pb_tabs][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ disabled_on=”on|on|on” _builder_version=”4.16″ disabled=”on” global_colors_info=”{}”][et_pb_row _builder_version=”4.16″ global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ global_colors_info=”{}”][:es _i=”0″ _address=”4.0.0.0″ \/][:en _i=”1″ _address=”4.0.0.1″ \/][: _i=”2″ _address=”4.0.0.2″ \/][\/et_pb_column][\/et_pb_row][\/et_pb_section]<\/p>\n","protected":false},"excerpt":{"rendered":"

Responsable Piedad N de Aza Moya   RESUMEN DE LA INVESTIGACI\u00d3N Los biomateriales son ampliamente utilizados en la actualidad en todas las especialidades cl\u00ednicas y agrupan a todas las clases y subclases de materiales. Ocupan un lugar importante en la econom\u00eda moderna y en la sociedad debido a una creciente demanda. La raz\u00f3n principal de […]<\/p>\n","protected":false},"author":17017,"featured_media":0,"parent":4234,"menu_order":41,"comment_status":"open","ping_status":"closed","template":"","meta":{"_et_pb_use_builder":"on","_et_pb_old_content":"","_et_gb_content_width":"","_links_to":"","_links_to_target":""},"_links":{"self":[{"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/pages\/4405"}],"collection":[{"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/users\/17017"}],"replies":[{"embeddable":true,"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/comments?post=4405"}],"version-history":[{"count":0,"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/pages\/4405\/revisions"}],"up":[{"embeddable":true,"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/pages\/4234"}],"wp:attachment":[{"href":"https:\/\/bioingenieria.umh.es\/en\/wp-json\/wp\/v2\/media?parent=4405"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}